FR2484617A1 - Domestic solar powered heating system - has full-height double skinned wall acting as air distribution duct and greenhouse built on one corner - Google Patents

Abstract

A solar house is constructed from dense brickwork having a high thermal inertia. A greenhouse is built onto the south-west corner. This receives high intensity solar radiation which is collected by one wall acting as an absorber and through the pebble floor of the greenhouse. Embedded in the pebble floor is a matrix of air ducts connected via a fan to a split wall built to full height through the middle of the house. The wall has outlets discharging either side into the adjacent room. Fresh air and exhaust lourvres, coupled with a central heating system are installed to cater for variations in the weather.

Description

SOLAR HEATING AND BUILDING PROCESS
TEAM FOR THE IMPLEMENTATION OF THIS PROCESS
The invention relates to a method of heating buildings, at least partially from solar energy; it extends to buildings made for the implementation of this process, in particular individual houses, small collective buildings, etc.

 Many studies have been carried out in recent years, on heating installations that use solar energy, with the aim of achieving consumption savings on traditional energy sources.

In particular, a frequently recommended system consists of providing a plurality of solar collectors in the form of panels exposed to solar radiation and of heating in these collectors a heat-transfer liquid, generally water, which is caused to circulate in radiators placed in the parts to be heated.

 However, these installations have several drawbacks. Firstly, they are ill-suited to condition an almost uniform temperature whatever the state of sunshine: these installations provide, during periods of full sunshine, excess calories which are lost and are unsuitable, in the absence of radiation in particular. at night, to provide a significant supply of heat.

 In addition, the additional cost of these installations is relatively high and is only amortized over very long periods of operation.

 In addition, solar collectors are in practice difficult to accommodate on the facade or roof of buildings and their presence is generally very unattractive.

 The present invention proposes to overcome the above-mentioned drawbacks of conventional solar heating installations.

 One of the objectives of the invention is in particular to allow good regulation of the interior temperature of the building during periods of sunshine and periods of non-sunshine.

 Another objective is to allow the realization of a building whose additional cost from the solar nature of heating is relatively reduced due to the simplicity of the additional elements required.

Another objective is to facilitate the integration of the collection means in the building and to allow to maintain the attractive character of the appearance of traditional buildings,
To this end, the method according to the invention consists in producing inside the building at least one cross wall made up of two thicknesses separated by an air space, to collect on at least one face of the building the solar radiation. to heat air, to send at least part of this air between the two thicknesses of the cross wall and to distribute it in the main rooms of the building by vents provided in said cross wall.

 The above-mentioned cross wall can be made with two thicknesses of high athermal inertia, each consisting of bricks of floor height, the vertical cells of which are filled with a material in the divided state of high thermal mass, in particular sand.

 In addition, according to another characteristic of the invention, the collection of solar radiation is ensured, at least partially, by a greenhouse arranged on one of the facades of the building, in particular on a facade exposed to the south or southwest for latitudes such as those of France, this greenhouse is delimited by a front glazing and by a rear absorbing wall of great thermal inertia, which constitutes one of the front walls of the building; This wall can be made, as before, by means of bricks of storey height filled with sand, the external face of said bricks being provided with a matte dark paint.

 The air heated in the greenhouse is preferably sent between the two thicknesses of the cross wall by means of ducts buried in a layer of pebbles, which forms the soil of the greenhouse.

 Part of the heated air from the greenhouse can also be sent directly to the adjacent rooms through openings in the absorbent wall.

 Furthermore, according to another characteristic of the method of the invention, the facade walls other than the absorbent wall are made so as to have a high thermal inertia and equipped with external insulation. They can in particular be produced, as previously, by bricks of storey height filled with sand, 'with a layer of insulating material, attached to said bricks of the outer side.

 Thus, in the method of the invention, the heating is carried out by means of air heated by solar energy, which is caused to yield part of its heat by convection to the thicknesses of the cross wall, this air then being blown in the main rooms. These are therefore heated in two ways, on the one hand, by emission of the external faces of the cross wall, on the other hand, by air blowing.

In addition, the cross wall, the front walls and the absorbent wall of the greenhouse, with great thermal inertia, accumulate a significant amount of calories during the periods of sunshine to then restore it, especially at night.

 Note that the rooms adjacent to the absorbent wall are also heated by emitting the interior face of this wall and, if necessary, by direct blowing of part of the air in the greenhouse.

 The collection means constituted by the greenhouse and its absorbent wall can be easily integrated into a facade of the building, without affecting the aesthetics of the latter; on the contrary, the greenhouse provided with plants can be a factor of improvement of the attractive aspect of this one.

 In addition, the various aforementioned means which use air as the sole heat transfer fluid are relatively modest in cost and the transfer of heat by means of the cross wall makes it possible to eliminate the exchangers and radiators which are necessary in conventional systems. , so that the method of the invention entralles small additional costs.

 In addition, in the hot season, the building can be ventilated by sending between the two thicknesses of the cross wall of fresh outside air when it is at a temperature below a given temperature the cross wall is used in this case to store frigories to refrigerate the building. Of course, the greenhouse is then obscured by an external blind or shutter reflecting the solar radiation.

The invention having been set out in its general form, the following description, with reference to the accompanying drawings, presents an embodiment by way of non-limiting example; on these drawings
FIG. 1 is a partial vertical section of a dwelling house, illustrating the process of the invention,
Figure 2 is a partial vertical section of the angle of this house exposed to
South West,
FIGS. 3 and 4 are sections similar to those of FIGS. 1 and 2, illustrating the operation in hot periods,
FIG. 5 is a schematic section of the house by a vertical plane, parallel to the cross wall and passing between the thicknesses of the latter,
FIGS. 6 and 7 are partial perspective views illustrating respectively the structure of the cross wall and of a front wall,
FIGS. 8 and 9 are plan views of the house respectively at the level of the ground floor and at the level of the floor,
Figures 10 and 11 are views similar to those of Figures 8 and 9, illustrating the operation in the hot season.

 The building shown by way of example in the figures to illustrate the process of the invention is a detached two-story dwelling house of which only the characteristics which have a direct link with the invention will be described.

 This house has on its SOUTH facade a greenhouse 1 comprising an inclined front glazing 2, an absorbing rear wall 3 and a pebble floor 4.

 At the WEST facade, the greenhouse 1 is closed by vertical glazing 5 which continues beyond the SOUTH-WEST angle of the house to produce a wall of the "Trombe" wall type with the absorbent wall 3.

 Glazing 2 and 5 are fitted with rolling shutters with adjustable louvers which are lifted in winter to let the solar radiation through and in summer allow the glazing to be obscured by reflecting the radiation. In addition, the glazing 2 is provided with fresh air intakes such as 7.

 The absorbent wall 3 is made of bricks of floor height in terracotta, with vertical cells filled with sand. Its external face is coated with a layer of black paint or other dark color paint.

 This wall includes high openings such as 8 and low (especially at the Trombe wall) such as 9, which open into the adjacent rooms.

 In the pebble floor 4 is buried a network of ducts 10, provided with lights or vents allowing the suction of air from the greenhouse. These ducts are connected to an air duct 11 equipped with means for circulating the air such as extractor 12. A fresh air duct 13 opening to the outside on a fresh facade of the house (North facade) is also connected to the extractor 12, which has two positions, a summer position in which it sucks in the fresh air through the conduit 13 and a winter position in which it sucks the air from the greenhouse through the conduit 11.

 Downstream of the extractor, the air duct opens into an interior cross wall 14 consisting of two walls 14a and 14b separated by an air space, which extend over the entire height of the house and over its entire length (from the east facade to the west facade).

 As shown schematically in Figure 6, each wall 14a or 14b of the crosswall is made of bricks of floor height, terracotta, whose vertical cells are filled with sand.

 As shown in Figure 5 (section parallel to the walls of the cross wall, at the level of the air space), between the walls 14a and 14b the air is guided by plates 15 along a preferred path passing through the vents such as 16 formed in the walls 14a or 14b and opening into the adjacent rooms. The plates 15 are open at their ends and pierced with openings such as 17 to allow air to diffuse throughout the air space separating the walls 14a and 14b of the cross wall.

 The cross wall which extends over the entire length of the house and has a large surface area forms a very large thermal mass for heat storage in addition, it makes it possible to conveniently distribute the air in an appropriate manner to the various rooms thanks to simple mouths 16 suitably positioned.

 Furthermore, the front walls of the house are made as shown in FIG. 7, in bricks of floor height 18, in terracotta, the vertical cells of which are filled with sand 19. On the external side, these bricks are equipped with an insulating layer 20, for example a layer of polystyrene 4 cm thick. A sealed external plaster 21 is placed on this layer with the interposition of conventional means improving the attachment thereof.

 In addition, the house is provided with additional heating means, preferably electric, but which can possibly use any traditional source. It is equipped with a regulation system, of a type known per se, adapted to ensure, on the one hand, the operation of this auxiliary heating below a minimum temperature inside the building, on the other hand, a cessation of the circulation of air heated by solar energy beyond a maximum temperature inside the building. For this purpose, conventional type temperature sensors are placed inside the house.

 The regulation system also includes one or more temperature probes arranged in the greenhouse 1, in order to interrupt the circulation of the air heated by solar energy, in the case where the temperature of this air drops below d '' a specified limit temperature; this arrangement avoids, in the event of a low temperature in the greenhouse, that the calories from the auxiliary heating are dissipated unnecessarily by the arrival of cold air.

 For example, in the cold season, the interior sensor of the building can trigger the operation of the auxiliary heating from a minimum temperature of the order of 18ex, and interrupt the circulation of the heated air above an interior temperature of the order of 22 ec e In addition, the probe located in the greenhouse 1 can stop the circulation of air in the greenhouse when it drops below 19 C.

Figures la 2, 8 and 9 illustrate the operation of the system in the cold season. The air in the greenhouse is heated, on the one hand, by the greenhouse effect behind glazing 2 and 5, on the other hand, by remission of the absorbent wall which absorbs part of the calories, accumulates them and re-emits them towards the greenhouse. and to the adjacent rooms
The heated air is sucked into the ducts 10 which also receive calories by contact with the rollers 4 This air is delivered into the split wall 14 to which it transfers part of its heat, the other being used to directly heat the parts in which this air is blown through the vents 16.

 The two walls of the cross wall 14 accumulate heat which they then restore during periods of non-sunshine.

 / ièCeEy in addition to the front walls heated by the ambient air / also provide heat storage which is returned during colder periods, especially at night.

 In this way, by means of considerable heat storage (at the level of the absorbent wall of large thermal mass, of the split wall of large thermal mass and of the facade walls of large thermal mass and isolated from the outside), natural temperature regulation is obtained. , which; combined with an efficient and discreet solar collection from an aesthetic point of view, provides a particularly efficient, economical unit capable of being integrated into the architecture of most buildings or houses.

 The system also has the advantage of being reversible in the hot season and of allowing storage of frigories.

 Figures 3, 4, 10 and 11 illustrate operation in the hot season. The greenhouse is open or concealed by means of rolling shutters 6 and the extractor / sucks in fresh air from the outside through the duct 13. A temperature sensor placed outside makes it possible to supply outside air when it -this is at a temperature below a determined temperature and to interrupt this blowing in the opposite case.

 For example, this blowing can be provided at night; the frigories thus transferred are essentially accumulated in the cross wall and condition excellent temperature regulation, avoiding any rise in temperature inside the house.

 Of course, the invention is not limited to the mes of the previous description, but includes all / variations. It is for example possible to provide several partition walls inside the building, arranged to give an appropriate heat storage and allow a satisfactory distribution in the rooms according to their distribution.

 In addition, the absorbent wall, cross wall and facade wall, of great thermal inertia, can if necessary, be produced by other means than those described, the latter being preferential - but not exclusive because of their high efficiency. and their moderate cost.

Claims (17)

 1 / - Method for at least partial heating of a building by means of solar energy, characterized in that it consists in producing inside the building at least one cross wall (14) consisting of two thicknesses (14a , 14b) separated by an air space, to capture on at least one face of the building the solar radiation to heat air, to send at least a part of this air between the two thicknesses (14a, 14b) of the wall and to distribute it in the main rooms of the building by mouths (16) formed in said partition wall.  2 / - Method according to claim 1, characterized in that one realizes the cross wall (14) with two thicknesses of high thermal inertia.  3 / - Method according to claim 2, characterized in that each thickness (14a or 14b) of the cross wall is made of bricks of storey height arranged vertically with vertical cells filled with a material riau in the divided state high thermal mass, especially sand.  4 / - Method according to one of claims 1, 2 or 3, characterized in that the air is guided between the two thicknesses (14a, 14b) of the cross wall along a preferred path passing at the mouths (16) .  5 / - Method according to one of claims 1, 2, 3 or 4, characterized in that the collection of solar radiation is ensured by a greenhouse (1) disposed on one of the facades of the building and delimited by a front glazing (2 , 5) and by a rear absorbent wall (3) of great thermal inertia constituting one of the front walls of the building.  6 / - Method according to claim 5, characterized in that the heated air from the greenhouse (1) is sent between the thicknesses (14a, 14b) of the cross wall by means of sheaths (10) buried in a layer of pebbles (4) forming the soil of the greenhouse.  7 / - Method according to one of claims 5 or 6, characterized in that the absorbent wall (3) of the greenhouse is made of bricks of floor height, arranged vertically with vertical cells filled with a material l divided state of high thermal mass, in particular by sand, the external face of the bricks being provided with a matte dark paint.  8 / - Method according to one of claims a 6 or 7, characterized in that part of the heated air from the greenhouse (1) is sent directly to the adjacent rooms by openings (8) made in the wall absorbent.  9 / - Method according to one of claims 5, 6, or 7, characterized in that the front walls of the building other than the absorbent wall are oralized so as to have a high thermal inertia, with external insulation (20) .  10 / - Method according to claim 9, ca acterized in that the facade walls are made of brick (18) of storey height, arranged vertically with vertical cells filled with a material in the divided state (19) of high thermal mass, in particular sand, a layer (-) of an insulating material being attached to said bricks on the outside.  11 / - Method according to one of claims 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10, in which a traditional backup heating is provided and a regulation realizing, on the one hand the switching on this auxiliary heating below a minimum temperature inside the building, on the other hand, stopping the circulation of air heated by solar energy above a maximum temperature inside said building.  12 / - Method according to one of claims 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 or 11, in which the circulation of air heated by solar energy is interrupted in the case the temperature of this air drops below a determined limit temperature.  13 / - Method according to one of claims 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12, allowing ventilation of the building in hot season, characterized in that, in season hot, outside air is sent between the two thicknesses (14a, 14b) of the cross wall when it is at a temperature below a determined temperature.  14 / - Building provided with solar heating means for implementing the method according to one of the preceding claims.  15 / - Building according to claim 14, characterized in that it comprises at least one internal cross wall (149 of great thermal inertia constituted by two thicknesses (14a, 14b) separated by an air space, air outlets <16) formed in said cross wall towards the main rooms, front walls of large thermal inertia insulated from the outside, means for collecting solar energy with a view to heating air, ducts ( 10,11) for distributing the heated air to the space between the two thicknesses of the cross wall and means 112) for circulating the air in said ducts.  16 / - Building according to claim 15, ca characterized in that the cross wall (14) consists of two thicknesses (14a, 14b) each formed by terracotta bricks of floor height arranged vertically with vertical cells filled with sand, the front walls being constituted by bricks (18) in terracotta of height of stage, arranged vertically with vertical cells filled with sand (19) and a layer of insulation (20) attached to the external face bricks.  17 / - Building according to one of claims 15, or 16, characterized in that the means for collecting solar energy comprise a greenhouse <1) delimited by a front window (2, 5) and a rear absorbent wall (3) constituted by terracotta bricks of shelf height arranged vertically with vertical cells filled with its blea, their external face being provided with a dark mat paint.